Digital signal processing device and a method and a Δ-σ sigma modulator using the same method

ABSTRACT

A signal processing device uses a ΔΣ modulator having varying effective orders to ensure an S/N ratio by selecting a high order when a 1-bit music signal is output via the ΔΣ modulator. The signal processing device prevents noise during switchover by shifting to a low order just before the ΔΣ modulator is bypassed if this occurs. The present invention provides a digital signal processing device which can switch between an original sound signal and a ΔΣ modulation signal and yield a sufficient S/N ratio for a reprocessed ΔΣ modulation signal. If any 1-bit original sound signal is input, little switching noise is generated.

BACKGROUND OF THE INVENTION

The present invention relates to a digital signal processing device, amethod, and a ΔΣ modulator for applying edit processing, such as volumeadjustment and the like, to digital audio data using high-speed 1-bitdata.

A method called delta-sigma (ΔΣ) modulation is proposed to digitizevoice signals. 1 (1. Yamazaki, Yoshio. “AD/DA Converter and DigitalFilter.” Journal of the Acoustical Society of Japan 46, No. 3 (1990):pp. 251-257.)

FIG. 1 is a block diagram of a ΔΣ modulation circuit for applying ΔΣmodulation to, e.g., 1-bit digital data. In FIG. 1, an input audiosignal S is supplied from an input terminal 81 to an integrator 83 viaan adder 82. This signal from the integrator 83 is supplied to acomparator 84. The signal is compared to a mid-point potential of, e.g.,the input audio signal S and is quantized on a 1-bit basis everysampling period. The frequency for the sampling period (samplingfrequency) is 64 or 128 times the conventional frequency 48 kHz or 44.1kHz.

This quantized data is supplied to a 1-sample delay circuit 85 and isdelayed for one sampling period. This delay data is converted to ananalog signal in, e.g., a 1-bit D/A converter 86, is added to the adder82, and is added to the input audio signal S from the input terminal 81.The quantized data output from the comparator 84 is generated as 1-bitdata D1 from an output terminal 87. According to ΔΣ modulationprocessing of this ΔΣ modulation circuit, as described in theabove-mentioned document, it is possible to generate audio signals witha high dynamic range using s small number of bits, such as 1 bit, bysufficiently increasing the sampling frequency. It also is possible toprovide a wide transmittable frequency band. The ΔΣ modulation circuitis suited for circuit configuration integration and can relativelyeasily provide A/D conversion accuracy. The ΔΣ modulation circuit iswidely used in an A/D converter, for example. A simple analog low-passfilter can be used for restoring the ΔΣ-modulated signal to an analogaudio signal. By using these features, the ΔΣ modulation circuit can beapplied to recorders and data transmission for handling high-qualitydata.

The above-mentioned ΔΣ modulation circuit thus generates 1-bit data formusic data. In order to edit such music data using a high-speed 1-bitsystem, the following operation is needed, as disclosed in JapanesePatent Application Laid-Open Publication No. 9-307452 submitted by theapplicant of the present invention. In the 1-bit data editing unit 90shown in FIG. 2, 1-bit input data D1 i is input as music data from aninput terminal 91. In a multiplier 92, D1 i is multiplied by a specifiedfactor k to temporarily convert to multi-bit data Dm. This data is againΔΣ-modulated in a ΔΣ modulator 93 to be restored to 1-bit signal D1′.The ΔΣ modulator 93 is a multistage modulator in a plurality of ordersusing a plurality of integrators and has a more complicatedconfiguration than for the ΔΣ modulation circuit in FIG. 1.

However, the above-mentioned configuration always lets signals pass theΔΣ modulator 93. Even if no volume adjustment or the like is needed,namely, the factor k is 1.0, music data D11 always passes the ΔΣmodulator 93, degrading sound quality. A fraction eliminator 94 is usedfor performing specified addition and subtraction to eliminate afraction remaining in an integrator inside the ΔΣ modulator 93. Thisoperation approximates patterns for an original sound signal D11 and aΔΣ modulation signal D1′. A delay circuit 96 is used to approximatelyalign phases for the ΔΣ modulation signal D1′ and the original soundsignal D1 i. A control unit 97 monitors signal patterns for the ΔΣmodulation signal D1′ and the original sound signal D11. When thesepatterns almost match, a selector 95 is switched to side a for thedelayed original sound signal D1 d from side b for the ΔΣ modulationsignal D1′.

When no volume adjustment or the like is needed, this process can switchthe ΔΣ modulation signal D1′ over to the delayed original sound signalD11 and generate a 1-bit data output from an output terminal 95 withoutgenerating a switching noise or the like. This process also can bypassreprocessing in the ΔΣ modulator 93.

However, noise may be generated during this switching operation,depending on the specifications of the ΔΣ modulator 93 to be used andthe frequency of the 1-bit data D11 to be input. Generally, a high-orderΔΣ modulator can provide a high S/N ratio in an audible band. On theother hand, frequency characteristics change at a point near the audibleband. A phase can easily rotate at a high frequency. When high-order ΔΣmodulation is used and the input signal frequency is high, a leveldifference and a phase shift occurs between the delayed original soundsignal D11 and the ΔΣ modulation signal D1′. Noise occurs when theselector 95 switches between these signals.

When the low-order ΔΣ modulator 93 is used, it hardly generates a noiseduring switchover because of little level difference and phase rotation.On the other hand, the audible band causes a low S/N ratio, lowering theS/N ratio when the ΔΣ modulator 93 is not bypassed.

BRIEF SUMMARY OF THE INVENTION

The present invention has been made in consideration of the foregoing.It is, therefore, an object of the present invention to provide adigital signal processing device having a simple configuration, amethod, and a ΔΣ modulator for switching between an original soundsignal and a ΔΣ modulation signal and providing a sufficient S/N ratiofor a reprocessed ΔΣ modulation signal with little switching noisegenerated after input of any 1-bit original sound signal.

For solving the above-mentioned problems, a digital signal processingdevice according to the present invention comprises: multiplicationmeans for multiplying an input ΔΣ modulation signal generated from ΔΣmodulation by a factor; ΔΣ modulation means having a plurality ofintegrators for varying effective orders and applying ΔΣ modulationagain to an output from the multiplication means; and switchover meansfor switching between a reprocessed ΔΣ modulation signal from the ΔΣmodulation means and the input ΔΣ modulation signal.

This digital signal processing device uses a ΔΣ modulator with variableeffective orders by changing orders for ΔΣ modulation signal output andthe original sound signal.

For solving the above-mentioned problems, a digital signal processingmethod according to the present invention comprises: a multiplicationstep for multiplying an input ΔΣ modulation signal generated from ΔΣmodulation by a specified factor for specified processing; a reprocessedΔΣ modulation step for reapplying ΔΣ modulation to an output providedwith said specified processing by using a ΔΣ modulator comprising aplurality of integrators for varying effective orders; and a switchoverstep for switching between said input ΔΣ modulation signal and saidreprocessed ΔΣ modulation signal.

For solving the above-mentioned problems, a ΔΣ modulator according tothe present invention for applying ΔΣ modulation to a multi-bit signalcomprises: a plurality of integrators; and order variation means forvarying effective orders increasing due to connection with a pluralityof said integrators.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a basic configuration diagram of a ΔΣ modulator forgenerating;

FIG. 2 is a block diagram showing a configuration of a conventional1-bit data editing unit;

FIG. 3 is a block diagram showing a configuration of a 1-bit dataediting unit according to an embodiment of the present invention;

FIG. 4 shows a detailed configuration of a ΔΣ modulator constituting theabove-mentioned 1-bit data editing unit; and

FIG. 5 is a frequency characteristics diagram of the above-mentioned ΔΣmodulator.

DETAILED DESCRIPTION OF THE INVENTION

Embodiments of the present invention will be described in further detailwith reference to the accompanying drawings. As shown in FIG. 3, thisembodiment is a 1-bit data editing unit 10 which applies edit processingincluding fading such as fade-in and fade-out to music data D11comprising 1-bit data resulting from ΔΣ modulation.

The 1-bit data editing unit 10 comprises a multiplier 12, a ΔΣ modulator13, a delay circuit 17, a selector 16, and a control unit 18. Themultiplier 12 multiplies input 1-bit data D11 by a factor k. The input1-bit data D11 is the above-mentioned music data to be input to an inputterminal 11. The ΔΣ modulator 13 comprises, e.g., five integrators andreapplies ΔΣ modulation to a multiplied output from the multiplier 12 byvarying effective orders, as will be described later. The delay circuit17 aligns a phase for the input 1-bit data D11 to the reprocessed ΔΣmodulation signal D1′ from the ΔΣ modulator 13. The selector 16 switchesbetween the delayed original sound signal D1 d output from the delaycircuit 17 and the reprocessed ΔΣ modulation signal D11. The controlunit 18 provides controls to vary the effective orders for the ΔΣmodulator 13.

As shown in FIG. 4, the ΔΣ modulator 13 is a 5-order (5-stage) ΔΣmodulator comprising five integrators 23, 33, 43, 50, and 57. Asmentioned above, the ΔΣ modulator varies effective orders according tosituations. This is to prevent noise for being generated duringswitchover between an original sound signal and a ΔΣ modulation signaldepending on the specifications of the ΔΣ modulator to be used and thefrequencies of input 1-bit data.

Generally, as shown in FIG. 5, the 3-, 4-, and 5-order ΔΣ modulatorsprovide higher S/N ratios as their orders increase. On the other hand,the point at which frequency characteristics change nears the audibleband, causing a phase to easily rotate at a high frequency. The ΔΣmodulator 13 switches the reprocessed ΔΣ modulation signal over to thedelayed original sound signal when the order becomes low enough to causesmall level differences and phase rotations at the high frequency.

The following describes the configuration of the ΔΣ modulator 13 indetail. The ΔΣ modulator 13 is configured as Z−1/(1−Z−1). In thisconfiguration, the first integrator 23 uses a delay circuit 26 to delayan addition output from an adder 27. The integrator 23 supplies thisoutput to a fraction eliminator 25 via a feedback loop 24, and thenreturns it to the adder 27 via the feedback loop 24.

The second integrator 33 also uses a delay circuit 36 to delay theaddition output from an adder 37, supplies this output to a fractioneliminator 35 via a feedback loop 34, and then returns it to the adder37 via the feedback loop 34.

Similarly, the third integrator 43 uses a delay circuit 46 to delay theaddition output from an adder 47, supplies this output to a fractioneliminator 45 via a feedback loop 44, and then returns it to the adder47 via the feedback loop 44.

Likewise, the fourth integrator 50 uses a delay circuit 53 to delay theaddition output from an adder 54, supplies this output to a fractioneliminator 52 via a feedback loop 51, and then returns it to the adder54 via the feedback loop 51.

The fifth integrator 57 has no fraction eliminator. The integrator 57uses a delay circuit 59 to delay the addition output from an adder 60,and then returns it to the adder 60 via the feedback loop 58.

The ΔΣ modulator 13 comprises an adder 22, a multiplier 28, and a leveladjuster 29. The adder 22 adds ΔΣ multiplication output from themultiplier 12 in FIG. 3 to quantized data fed back from a quantizer 61,to be described later. The quantized data has an inverted sign. Themultiplier 28 multiplies the integral output from the first integrator23 by the first order control factor j1 supplied from an order controlcircuit 14. The level adjuster 29 multiplies the multiplication outputfrom the multiplier 28 by an appropriate gain.

The ΔΣ modulator 13 comprises a multiplier 30 and an adder 32. Themultiplier 30 multiplies the multiplication output from the multiplier12 by the second order control factor j2 supplied from the order controlcircuit 14. The adder 32 adds the multiplication output from themultiplier 30, the level adjustment output from the level adjuster 29,and quantized data with an inverted sign supplied from the quantizer 61to generate an addition output. The adder 32 then supplies this additionoutput to the second integrator 33.

The ΔΣ modulator 13 comprises a multiplier 38 and a level adjuster 39.The multiplier 38 multiplies an integral output from the secondintegrator 33 by a third order control factor j3 supplied from the ordercontrol circuit 14. The level adjuster 39 multiplies a multiplicationoutput from the multiplier 38 by an appropriate gain.

The ΔΣ modulator 13 comprises a multiplier 40 and an adder 42. Themultiplier 40 multiplies a multiplication output from the multiplier 12by a fourth order control factor j4 supplied from the order controlcircuit 14. The adder 42 adds the multiplication output from themultiplier 40, the level adjustment output from the level adjuster 39,and quantized data with an inverted sign supplied from the quantizer 61to generate an addition output. The adder 42 then supplies this additionoutput to the third integrator 43.

The ΔΣ modulator 13 comprises a level adjuster 4B and an adder 49. Thelevel adjuster 48 multiplies an integral output from the thirdintegrator 43 by an appropriate gain. The adder 49 adds the leveladjustment output from the level adjuster 48 to quantized data with aninverted sign supplied from the quantizer 61 to generate an additionoutput. The adder 49 then supplies this addition output to the fourthintegrator 50.

The ΔΣ modulator 13 comprises a level adjuster 55 and an adder 56. Thelevel adjuster 55 multiplies an integral output from the fourthintegrator 50 by an appropriate gain. The adder 56 adΔΣ a leveladjustment output from the level adjuster 55 to quantized data with aninverted sign supplied from the quantizer 61 to generate an additionoutput. The adder 56 then supplies this addition output to the fifthintegrator 57.

Further, the ΔΣ modulator 13 comprises a quantizer 61. The quantizer 61quantizes the integral output from the fifth integrator 57 to generatequantized data from an output terminal 62. The quantizer 61 also feeΔΣthis data back to the adders 22, 32, 42, 49, and 56.

The following describes the basic operations of the ΔΣ modulator 13. Theinput terminal 21 is supplied with a multi-bit music signal that isoutput from the multiplier 12. This music signal is supplied to theadder 22 and is added to a feedback signal supplied from the quantizer61. This feedback signal is quantized data with an inverted sign. As aresult, the quantized data is subtracted from the music data. An outputfrom the adder 22 is supplied to the first integrator 23.

The first integrator 23 has the above-mentioned configuration. Thefraction eliminator 25 eliminates a fraction from the data delayed inthe delay circuit 26. The feedback loop 24 returns this data to theadder 27. Integration is performed by repeating addition to an adder22's output supplied to the adder 27. The integral output from the firstintegrator 23 is supplied to the multiplier 28 and is multiplied by thefirst order control factor j1 from the order control circuit 14. Theorder control circuit 14 outputs the first order control factor j1 whoseinitial value is 1.0.

The music signal is input from the input terminal 21. The multiplier 30multiplies this music signal by the second order control factor j2output from the order control circuit 14. The initial value of thissecond order control factor j2 is 0.0. Accordingly, the multiplier 28provides no operation. The level adjuster 29 multiplies the output fromthe first integrator 23 by the appropriate gain. The adder 32 then addsthe feedback signal to this output and passes it to the secondintegrator 33.

The second integrator 33 has the above-mentioned configuration. Thefraction eliminator 35 eliminates a fraction from the data delayed inthe delay circuit 36. The feedback loop 34 returns this data to theadder 37. Integration is performed by repeating addition to an adder32's output supplied to the adder 37. The integral output from thesecond integrator 33 is supplied to the multiplier 38 and is multipliedby the third order control factor j3 from the order control circuit 14.The initial value of this third order control factor j3 is 1.0.

The music signal is input from the input terminal 21. The multiplier 40multiplies this music signal by the fourth order control factor j4output from the order control circuit 14. The initial value of thisfourth order control factor j4 is 0.0. Accordingly, the secondintegrator 33 operates like the first integrator 23.

The same processing occurs from the third integrator 43 to the fifthintegrator 57. The quantizer 61 quantizes data to 1 bit. This 1-bit datais used as a feedback signal and is reflected on the operation result ofthe next stage.

Thus, the 5-order ΔΣ modulator 13 shifts a quantized noise to a highfrequency and generates a 1-bit output signal out of multi-bit inputdata.

The following describes how the ΔΣ modulator 13 varies orders. The ordercontrol circuit 14 outputs the second order control factor j2 to themultiplier 30. The second order control factor j2 gradually increasesfrom 0.0 and changes to 1.0 within a given time. The first order controlfactor j1 is expressed as follows:(first order control factor j1)=1.0−(second order control factor j2)

The first order control factor j1 changes from 1.0 to 0.0 in the sametime interval as for the second order control factor j2. When the firstorder control factor j1 becomes 0.0, this means that a feedback signalset to 0 enters the first integrator 23 and the first stage.

Since the second order control factor j2 is 1.0, this means that a musicsignal is directly input to the second integrator 33 via the adder 32.According to these operations, the ΔΣ modulator 13 seamlessly shiftsfrom the fifth to the fourth order and finally becomes the completefourth ΔΣ modulator.

In exactly the same way, it is possible to seamlessly change the ΔΣmodulator 13 to the third order by controlling the third order controlfactor j2 and the fourth order control factor j4. It is also possible tochange from the fifth, the fourth, then to the third order,alternatively, from the fifth to the third order.

The following describes the operations of the 1-bit data editing unit 10in detail with reference back to FIG. 3. In FIG. 3, like the prior art,a 1-bit data D11 is input to the input terminal 11 as an original soundsignal. The multiplier 12 multiplies the input 1-bit data D11 by afactor k (any value) to generate a multi-bit multiplication output withan adjusted sound volume. The ΔΣ modulator 13 receives this output andconverts it to 1-bit data to generate the ΔΣ modulation signal D1′.

At this time, the selector 16 is set to the ΔΣ modulation signal D1′side b. When 1-bit data is output, the ΔΣ modulation signal D1′ isoutput. When the factor k becomes 1.0, the multi-bit multiplicationoutput may be assigned a weight 1. In this case, all bits below theweight 1 are reset to 0 s. The ΔΣ modulator 13 is not provided with datasmaller than or equal to 1 (hereafter referred to as the fraction).

Detecting that the factor k becomes 1.0, the control unit 18 issues aninstruction to the order control circuit 14 for lowering the order. Byreceiving this instruction, the order control circuit 14 controls thefirst order control factor j1 through the fourth order control factor j4for lowering the order from the fifth to the fourth or to the third, asmentioned above.

When the ΔΣ modulator 13 finishes shifting to the lower order, thecontrol unit 18 issues an instruction for eliminating the fraction tothe fraction eliminator 15. The fraction eliminator 15 comprises thefraction eliminators 25, 35, 45, and 52, each connected to theintegrators. The fraction eliminator 15 eliminates a fraction remainingin each integrator by adding or subtracting a slight amount of DC.

When the fraction has been removed, the control unit 18 compares the ΔΣmodulation signal D1′ with the delayed original sound signal D11. Whenthe output patterns match within an appropriate range, the control unit18 switches the selector 16 over to the delayed original sound signalD11 side a.

The ΔΣ modulator 13 switches the ΔΣ modulation signal over to theoriginal sound signal when the order becomes low enough to cause smalllevel differences and phase rotations at the high frequency. Thechangeover should be available without generating a noise, even if theoriginal sound signal contains a high-frequency signal exceeding theaudible band. At this time, the changeover time just takes several tensof milliseconds. A low S/N ratio causes no significant problem while thelow order takes effect.

The series of operations described above applies when an output ΔΣmodulation signal is used for volume adjustment or the like, then noadjustment or the like becomes necessary, and finally the output signalis switched to the original sound signal. When the adjustment or thelike is needed again, the following operations apply.

While the factor k is 1.0, the ΔΣ modulator 13 keeps operating with thethird order unchanged. Specifically, the order control circuit 14 usesthe second order control factor j2 set to 1.0, the first order controlfactor j1 set to 0.0, the fourth order control factor j4 set to 1.0, andthe third order control factor j3 set to 0.0.

Just before the factor k changes from 1.0 to a different value, thecontrol unit 18 compares the delayed original sound signal D1 d with theΔΣ modulation signal D1′. When the output patterns match within anappropriate range, the control unit 18 switches the selector 16 over tothe ΔΣ modulation signal 1′ side b. At this time, the ΔΣ modulator 13 isset to the third order. No noise occurs even if the original soundsignal contains a high-frequency component. The output is switched overto the ΔΣ modulation signal 1′.

When detecting that the selector 16 is switched, the order controlcircuit 14 smoothly changes the third order control factor j3 from 0.0to 1.0. Concurrently, the order control circuit 14 changes the fourthorder control factor j4 from 1.0 to 0.0. Since the second order controlfactor j2 is set to 1.0, the ΔΣ modulator 13 changes to the fourthorder.

When this operation is complete, the second order control factor j2smoothly changes to 0.0. The first order control factor j1 smoothlychanges to 1.0. The ΔΣ modulator 13 changes to the fifth order.Consequently, subsequent outputs become fifth ΔΣ modulation outputs,ensuring a sufficient S/N ratio.

As mentioned above, the ΔΣ modulator 13 can smoothly change orders fromthe fifth to the third. Using this, the 1-bit data editing unit 10ensures the S/N ratio by maintaining the fifth order when a ΔΣmodulation signal is output for a long period.

When the output is switched to the original sound signal, the 1-bit dataediting unit 10 decreases the switching noise due to a level differenceand a phase rotation by dropping the order to the third just before theswitchover.

Though the above example uses the fifth ΔΣ modulator as a basis, it maybe the fourth, sixth, or seventh order. The ΔΣ modulator may be droppeddown to the second or the first as needed. In the above-mentionedoperation description, the factor k is set to 1.0 or another value. Whenthe factor k is set to 0.0, the order is decreased likewise.

Then, the ΔΣ modulation signal is switched to a fixed-pattern signalrepresenting no sound. If the input/output frequency characteristicssatisfy intended conditions, the order control circuit 14 may output thesecond order control factor j2 and the fourth order control factor j4always fixed to 1.0.

The integrator is configured as Z−1/(1−Z−1). If the input/outputfrequency characteristics satisfy intended conditions, the configurationmay be 1/(1−Z−1). The multipliers 28 and 38 may be unified. Theimmediately subsequent level adjusters 29 and 39 also may be unified.

The ΔΣ modulator and input/output signals may comprise not only one bit,but also a plurality of bits.

1. A digital signal processing device comprising: multiplication meansfor multiplying an input ΔΣ modulation signal generated from ΔΣmodulation by a factor; ΔΣ modulation means having a plurality ofintegrators for varying effective orders and applying ΔΣ modulationagain to an output from said multiplication means; and switchover meansfor switching between a reprocessed ΔΣ modulation signal from said ΔΣmodulation means and said input ΔΣ modulation signal.
 2. The digitalsignal processing device according to claim 1, wherein said ΔΣmodulation means comprises order control means for varying effectiveorders depending on signal switchover situations in said switchovermeans.
 3. The digital signal processing device according to claim 2,wherein said order control means varies effective orders for said ΔΣmodulation means at an approximate timing when said switchover meansswitches between said input ΔΣ modulation signal and said reprocessed ΔΣmodulation signal.
 4. The digital signal processing device according toclaim 2, wherein said order control means varies effective orders forsaid ΔΣ modulation means at an approximate timing when said switchovermeans switches between a fixed signal changing to no sound in an audibleband and music data processed with ΔΣ modulation.
 5. The digital signalprocessing device according to claim 1, wherein said ΔΣ modulation meanscomprises fraction elimination means for eliminating a fractionremaining in said integrator.
 6. A digital signal processing method,comprising steps of: a multiplication step for multiplying an input ΔΣmodulation signal generated from ΔΣ modulation by a specified factor forspecified processing; a reprocessed ΔΣ modulation step for reapplying ΔΣmodulation to an output provided with said specified processing by usinga ΔΣ modulator comprising a plurality of integrators for varyingeffective orders; and a switchover step for switching between said inputΔΣ modulation signal and said reprocessed ΔΣ modulation signal.
 7. Thedigital signal processing method according to claim 6, wherein saidreprocessed ΔΣ modulation step varies effective orders for said ΔΣmodulator depending on signal switchover situations in said switchoverstep.
 8. The digital signal processing method according to claim 7,wherein said reprocessed ΔΣ modulation step varies effective orders forsaid ΔΣ modulator at an approximate timing when said switchover stepswitches between said input ΔΣ modulation signal and said reprocessed ΔΣmodulation signal.
 9. The digital signal processing method according toclaim 7, wherein said reprocessed ΔΣ modulation step varies effectiveorders for said ΔΣ modulator at an approximate timing when saidswitchover step switches between a fixed signal changing to no sound inan audible band and music data processed with ΔΣ modulation.
 10. Thedigital signal processing method according to claim 6, wherein saidreprocessed ΔΣ modulation step not only varies effective orders for a ΔΣmodulator, but also eliminates a faction remaining in said integrator.11. A ΔΣ modulator for applying ΔΣ modulation to a multi-bit signalcomprising: an integrator of a plurality of integrators having fractionelimination means for eliminating a fraction remaining in saidintegrator, and order variation means for varying effective ordersincreasing due to connection with said plurality of said integrators,wherein said integrator further includes: an integrator adder thatreceives an output from said fraction elimination means; and anintegrator delay circuit that delays an output from said integratoradder, said delayed output from said integrator adder being provided tosaid fraction elimination means.
 12. The ΔΣ modulator according to claim11, wherein said fraction is data smaller than or equal to
 1. 13. The ΔΣmodulator according to claim 11, wherein said ΔΣ modulator receives aninput, an effective order of said effective orders being the number ofsaid integrators participating in the modulation of said input.
 14. TheΔΣ modulator according to claim 13, further comprising: a firstmultiplier, a first control factor supplied from said order variationmeans being received by said first multiplier to generate a firstmultiplication output, said first multiplier multiplying said input bysaid first control factor to generate said first multiplication output;a second multiplier, a second control factor supplied from said ordervariation means being received by said second multiplier to generate asecond multiplication output, said second multiplier multiplying anoutput from another integrator of said plurality of said integrators bysaid second control factor to generate said second multiplicationoutput.
 15. The ΔΣ modulator according to claim 14, further comprising:a first adder that generates a first addition output by adding saidinput and quantized data from a quantizer.
 16. The ΔΣ modulatoraccording to claim 15, wherein said another integrator receives saidfirst addition output.
 17. The ΔΣ modulator according to claim 14,further comprising: a level adjuster that multiplies said secondmultiplication output by a gain to generate a level adjustment; and asecond adder that generates a second addition output by adding saidfirst multiplication output, said level adjustment, and quantized datafrom a quantizer.
 18. The ΔΣ modulator according to claim 17, whereinsaid integrator receives said second addition output.
 19. The ΔΣmodulator according to claim 14, wherein:(said first control factor)=1.0−(said second control factor).
 20. The ΔΣmodulator according to claim 19, wherein said first control factor is“0.0” when said number of said integrators equals said plurality of saidintegrators.
 21. The ΔΣ modulator according to claim 19, wherein saidfirst control factor is “0.1” when said number of said integrators isless than said plurality of said integrators.